The p lambda CM system: phage immunity-specific incompatibility with IncP-1 plasmids

Summary A pCM2 replicon derived by an N^– deletion from ::Tn9 which carries the imm434 immunity region is incompatible with some (but not all) IncP-1 plasmids. The imm pCM1 replicon does not show the same incompatibility behavior.     

Complete sequence of the IncP-9 TOL plasmid pWW0 from Pseudomonas putida

The TOL plasmid pWW0 (117 kb) is the best studied catabolic plasmid and the archetype of the IncP-9 plasmid incompatibility group from Pseudomonas. It carries the degradative (xyl) genes for toluenes and xylenes within catabolic transposons Tn4651 and Tn4653. Analysis of the complete pWW0 nucleotide sequence revealed 148 putative open reading frames. Of these, 77 showed similarity to published sequences in the available databases predicting functions for: plasmid replication, stable maintenance and transfer; phenotypic determinants; gene regulation and expression; and transposition. All identifiable transposition functions lay within the boundaries of the 70 kb transposon Tn4653, leaving a 46 kb sector containing all the IncP-9 core functions. The replicon and stable inheritance region was very similar to the mini-replicon from IncP-9 antibiotic resistance plasmid pM3, with their Rep proteins forming a novel group of initiation proteins. pWW0 transfer functions exist as two blocks encoding putative DNA processing and mating pair formation genes, with organizational and sequence similarity to IncW plasmids. In addition to the known Tn4651 and IS1246 elements, two additional transposable elements were identified as well as several putative transposition functions, which are probably genetic remnants from previous transposition events. Genes likely to be responsible for known resistance to ultraviolet light and free radicals were identified. Other putative phenotypic functions identified included resistance to mercury and other metal ions, as well as to quaternary ammonium compounds. The complexity and size of pWW0 is largely the result of the mosaic organization of the transposable elements that it carries, rather than the backbone functions of IncP-9 plasmids.     

Isolation of an Hfr donor of Pseudomonas aeruginosa PAO by insertion of the plasmid RP1 into the tryptophan synthase gene

Summary A derivative of the IncP-1 plasmid RP1, temperature-sensitive for maintenance, was inserted into the Pseudomonas aeruginosa chromosome by selection for a plasmid marker (carbenicillin resistance) at nonppermissive temperature. In one strain, PAO 1000, the plasmid was stably integrated in the trpA, B gene cluster mapped at 27 min, as shown by the following evidence. (i) Trp⁺ transductants lost all plasmid markers. (ii) Cleared lysates of PAO 1000 showed no plasmid band typical of the autonomous RP1 in agarose gel electrophoresis. (iii) No transfer of carbenicillin resistance by PAO 1000 was detectable. (iv) PAO 1000 mobilised the chromosome from an origin at, or very near, the plasmid insertion site with high frequency (recovery of proximal markers 10^–3 per donor). Matings on the plate with and without interruption of conjugation showed that chromosome transfer was unidirectional. (v) Recombinants from PAO 1000-mediated crosses did not inherit plasmid markers or the trpA, B mutation. A derivative of PAO 1000 was obtained which had lost the Hfr property and all plasmid markers except carbenicillin resistance. This strain (PAO 1001), when carrying the autonomous RP1 plasmid, was capable of unidirectional chromosome mobilisation like PAO 1000, but with 50-fold lower efficiency. We propose that integration of the temperature-sensitive RP1 plasmid in PAO 1000 occurred via transposition of Tnl, the element specifying carbenicillin resistance.     

Cloning and localization of the replication and mobilization regions in the D-plasmid of Pseudomonas putida pBS286 (IncP-9) with a broad host range

Rep-mob loci of naphthalene degradative plasmid pBS286 (IncP-9) have been cloned on the Escherichia coli vectors pUC19 and pUBR322. These loci confer to recombinant plasmids pBS952 and pBS953 the ability for effective mobilization by RP4 (IncP-1) and F plasmid, as well as constant maintenance in various gram-negative bacteria. Localization of cloned sequences in the restriction fragments of conservative part of the pBS286 genome was established. The data obtained correlate with the analysis of plasmids pBS950 and pBS951 which are spontaneous mini-derivatives of pBS286 and pBS292 (delta NPL1::Tn1/Tra+ Nah-) plasmids formed during transformation of E. coli HB101 cells. Plasmids pBS952 and pBS953 retain the incompatibility properties of parental IncP-9 replicon. These recombinant derivatives can be used for construction of bhr vectors with required properties and compatible with bhr vectors constructed on the basis of plasmids from the IncP-1 and IncP-4 groups.     

The requirement for both DNA polymerase and 5'' to 3'' exonuclease activities of DNA polymerase I during Tn5 transposition

Summary By assaying transposition of Tn5 from b221 cI857 rex::Tn5 (Berg 1977) in PolA-proficient and deficient cells, both the polymerase activity and 5 to 3 exonuclease acivity of DNA polymerase I have been shown to be required for transposition. This requirement could not be observed in three other systems in which the transposon donor replicon had existed in the PolA-proficient and deficient cells before the transposition event to be assayed occurred. By analogy to Tn3, this may indicate that the repressor encoded by Tn5 has already been expressed and hence become rate-limiting in the overall transposition process, even in PolA-deficient cells still possessing a residual activity. One polA mutant was found among more than 50 transposition-deficient (tnp) mutants isolated by the use of b221 cI857 rex::Tn5.     

Sequence requirements for target activity in site-specific recombination mediated by the Int protein of transposon Tn 1545

Excision and integration of Tn 1545 occur by reciprocal site-specific recombination between 6 (or 7)bp variable sequences present in the recombining attachment (atf) sites and designated overlap regions. We devised an assay for Tn1545 transposition in which derivatives containing the cis-acting transposition sequences (atfTn 1545) integrate into a target replicon when complemented in trans by the transposon-encoded integrase Int-Tn. This assay was used to determine the characteristics of the DNA sequence that influence target site selection. Characterization of several integration sites indicated that a 20 bp segment, designated attB, contains the sequences required for target activity. It also appeared that (i) the target activity depends upon the extent of homology between the 7bp segments flanking the overlap regions in attB and attTn1545, and (ii) the degree of homology between the two recombining overlap regions does not affect the level of target activity and has no influence on integration orientation.     

In vivo Tn<Emphasis Type="Italic">5</Emphasis>-based transposon mutagenesis of Streptomycetes

This paper reports the in vivo expression of the synthetic transposase gene tnp(a) from a hyperactive Tn5 tnp gene mutant in Streptomyces coelicolor. Using the synthetic tnp(a) gene adapted for Streptomyces codon usage, we showed random insertion of the transposon into the Streptomycetes genome. The insertion frequency for the hyperactive Tn5 derivative is 98% of transformed S. coelicolor cells. The random transposition has been confirmed by the recovery of ~1.1% of auxotrophs. The Tn5 insertions are stably inherited in the absence of apramycin selection. The transposon contains an apramycin resistance selection marker and an R6Kγ origin of replication for transposon rescue. We identified the transposon insertion loci by random sequencing of 14 rescue plasmids. The majority of insertions (12 of 14) were mapped to putative open-reading frames on the S. coelicolor chromosome. These included two new regulatory genes affecting S. coelicolor growth and actinorhodin biosynthesis.     

Does Tn10 transpose via the cointegrate molecule?

Summary It has been well established that Tn3 and its relatives transpose from one replicon to another by two successive reactions: formation of the cointegrate molecule and resolution from it. Whether or not the 9300 base pair tetracycline resistance transposon Tn10 transposes in the same manner as Tn3 was investigated by two methods.In the first method, 55, a lambda phage carrying Tn10 was lysogenized in an Escherichia coli strain carrying a Tn10 insertion; the phage has a deletion in attP, hence it was lysogenized in a Tn10 sequence in the E. coli chromosome by reciprocal recombination. The chromosomal structure in these lysogens is equivalent to the Tn10-mediated cointegrate molecule of lambda and the E. coli chromosomal DNA. The stability of the cointegrate molecule was examined by measuring the rate of excision of lambda from the host chromosome, and was found to be stable, especially in a Rec^- strain. Because of this stability, the cointegrate molecule should be accumulated if Tn10 transposes via the cointegrate molecule. Then, we examined the configuration of products made by transposition of Tn10 from 55 to the E. coli chromosome. The cointegrate molecule was found in products of Tn10 transposition in a Rec⁺ strain at a frequency of 5% per Tn10 transposition, but this molecule could not be found in a Rec^- strain. Since transposition of Tn10 was recA-independent, absence of the cointegrate molecule formed in a RecA^- strain strongly suggested that the cointegrate molecule is not an obligatory intermediate of transposition of Tn10.In the second method, mobilization of pACYC177 by R388 and by R388:: Tn10 was examined. The pACYC177 plasmid was mobilized by R388::Tn10 at a frequency of 10^-4 per donor but not by R388. It occurred, in most cases, by inverse transposition of R388::Tn10 to pACYC177 forming plasmids such as pACYC177::IS10-R388-IS10. Mobilization of pACYC177 by a Tn10-mediated cointegrate in the form of pACYC177::Tn10-R388-Tn10 was not observed in crosses using a Rec^- donor. These observations also suggested that transposition of Tn10 in Rec^- cells does not occur via the cointegrate molecule.     

Molecular cloning into Tn5 and integration in the Pseudomonas aeruginosa chromosome: a tool for heterologous gene expression

The DNA primase gene of the promiscuous IncP-1 conjugative plasmid RP1, encoding two polypeptides of 118 and 80 kDa, was inserted into the transposon Tn5 in Escherichia coli. The derivative transposon, Tn2523, was then transposed to a temperature-sensitive replication mutant of the promiscuous IncP-1 conjugative plasmid R68 at permissive temperature and the plasmid transferred to Pseudomonas aeruginosa strain PAO. The latter strain was then grown at non-permissive temperature to identify transposition of Tn2523 into the P. aeruginosa chromosome. Immunological and enzymic analysis showed the expression of functional primase polypeptides in the constructed P. aeruginosa strain. This strain also restored wild-type conjugational transfer proficiency, by complementation, to mutants of the IncP-1 plasmid R18 affected in transfer from P. aeruginosa to P. stutzeri or to Acinetobacter calcoaceticus due to transposon Tn7 insertion mutations in the primase gene. This strategy of cloning into a transposon and integration into the bacterial chromosome should facilitate genetic manipulation and studies of gene expression in a range of Gram-negative bacteria.     

LexA protein of Escherichia coli represses expression of the Tn5 transposase gene.

The LexA protein of Escherichia coli represses expression of a variety of genes that, by definition, constitute the SOS regulon. Genetic evidence suggests that Tn5 transposition is also regulated by the product of the lexA gene (C.-T. Kuan, S.-K. Liu, and I. Tessman, Genetics 128:45-57, 1991). We now show that the LexA protein represses expression of the tnp gene, located in the IS50R component of Tn5, which encodes a transposase, and that LexA does not repress expression of the IS50R inh gene, which encodes an inhibitor of transposition. Elimination of LexA resulted in increased expression of the tnp gene by a factor of 2.7 +/- 0.4, as indicated by the activity of a lacZ gene fused to the tnp gene. LexA protein retarded the electrophoretic movement of a 101-bp segment of IS50R DNA that contained a putative LexA protein-binding site in the tnp promoter; the interaction between the LexA repressor and the promoter region of the tnp gene appears to be relatively weak. These features show that the IS50R tnp gene is a member of the SOS regulon.     

Genetic evidence for absence of transposition functions from the internal part of Tn981 a relative of Tn9

Summary Inverse transposition of the DNA of pBR322 was found to be mediated by the small transposon Tn981 a relative of Tn9 flanked by direct repeats of IS1. Since the resulting structure IS1:: pBR322::IS1 (Tn983) is transposed in a second step in the absence of Tn981, it is concluded that all the functions necessary for transposition of IS1 flanked transposons are coded for by IS1 itself or the E. coli chromosome, respectively.     

Structure of replication initiation region in <Emphasis Type="Italic">Pseudomonas</Emphasis> IncP-7 streptomycin resistance plasmid Rms148

Pseudomonas’ IncP-7 plasmids play significant role in the environmental biodegradative potential and sometimes carry antibiotic-resistance genes. Rms148 plasmid was used as archetypal P-7 plasmid in microbiological incompatibility studies for more then 30 years. However, the structure of its basic replicon was not described until now; furthermore, the phylogenetic relationships between all known plasmids within the IncP-7 group have not yet been studied. In the course of our study, we have constructed two pairs of primers to amplify the main components of the region of the initiation of P-7 replication, and the subsequent screening of repA intragenic polymorphism was performed using the laboratory collection of IncP-7 plasmids. The minimal replicon of Rms148 was determined and its nucleotide sequence was found to be 81–83% identical to repA-oriV of known P-7 plasmids and is considered to fall into a separate clade of the corresponding phylogenetic tree. Additionally, repA group members seem to be more conservative than the putative oriV region. The estimated amino acid sequence and predicted secondary and tertiary structures of Rms148 RepA protein allowed us to make the assumption that the initiation of replication in plasmids of the P-7 incompatibility group is described by the same model as for the unclassified cryptic plasmid pPS10.     

Behaviour of the transposons Tn5 and Tn7 in Xanthomonas campestris pv. campestris

Summary Xanthomonas campestris pv. campestris was tested for its ability to maintain various plasmids after they had been transferred by conjugation from Escherichia coli donors. Broad host-range plasmids belonging to incompatibility groups P and Q could be maintained but X. campestris was unable to support replication of narrow host-range ColE1, pACYC184 and pBR325 replicons. Delivery systems based on E. coli donors of suicide plasmids and on X. campestris Hfrs were used to introduce Tn7 and Tn5 into X. campestris. Tn7 insertions were recovered at high frequency while Tn5 transposed at low frequency. Three auxotrophic Tn5 insertions were isolated but transposition of Tn7 into the X. campestris genome did not generate any auxotrophs. DNA hybridization analysis showed that Tn7 had inserted into the same hot spot(s) in all cases tested.     

Replicon fusion mediated by a single-ended derivative of transposon Tn1721

Summary Tn17221K, a derivative of transposon Tn1721 lacking one terminal inverted repeat (IR) and conferring kanamycin resistance, promotes transposition of the resistance marker to a target replicon at about 100-fold lower frequency than the wild-type element. A study involving restriction analysis of 16 independent Tn17221K-mediated events led to the following results: (i) Tn17221K mediates fusions of the donor (pRU506) and target (RSF1010) replicons; the fused entities are non-permuted. (ii) Tn17221K promotes insertions of donor DNA at many different sites in the target replicon. (iii) The analyzed fusion plasmids contain the entire target and various lengths of donor DNA. Eleven products contain the entire donor plasmid plus a duplication of the IR (class A), whereas five products contain only portions adjacent to the single IR (class B). (iv) In each case the two replicons are joined at (or very close to) the single IR. The second junction is located shortly beyond the duplicated IR in class A and at different sites within the donor plasmid in class B. These results are interpreted in terms of asymmetric replicative transposition.     

IS8- and Tn2353-mediated cointegration of the plasmids R15 and RP4::Tn1

Summary The plasmids R15 and RP4:: Tn1 form fused structures (85 Md and 92 Md cointegrates). The cointegrates do not resolve practically in recA ^– Escherichia coli cells and have a mean life-time of more than 50 generations in a recA ⁺ background.The 85 Md cointegrates were generated at a frequency of 4×10^–4 per R15 transconjugant during a mating between E. coli [R15; RP4:: Tn1] and E. coli [FColVBtrp:: Tn1755]. These plasmids carry two directly repeated copies of the mobile element IS8 at the junctions between R15 and RP4:: Tn1. The transposition of IS8 from RP4:: Tn1 to the R15 plasmid and the formation of hybrid molecules promoted by this process appear to be induced by the IS8 element of the Tn1755 structure during or after conjugal transfer of FColVBtrp:: Tn1755 into E. coli [R15; RP4:: Tn1] cells.The formation of the 92 Md cointegrates occurs at a frequency of 2×10^–5. The fused molecules of R15 and RP4:: Tn1 carry two direct copies of an 8.65 Md R15 fragment at the junctions between these replicons. The fragment has specific features of a new transposon. This element designated Tn2353 determines resistance to Hg, Sm and Su and contains two sites for each BamHI, BglII and SalI and three sites for both EcoRI and PstI. The physical map and some other characteristics of Tn2353 are presented.Abbreviations Ap ampicillin - EtBr ethidium bromide - Km kanamycin - Md megadaltons - Sm streptomycin - Su sulfanilamide - Tc tetracycline - [] brackets indicate plasmid-carrier state     

The effect of tnm mutations of Escherichia coli K12 on transposition of various movable genetic elements

Summary The effects of different tnm mutations on the transposition of Tn3, Tn5, Tn10, Tn601, and bacteriophage Mu were studied. Five tnm mutations were placed into three phenotypic classes. The representatives of the first class, tnm-1 and tnm-2, caused a complete block of transposition of all Tn-elements studied; the representatives of the second class, tnm-3 and tnm-4, specifically affected Tn9 transposition while the tnm-5 mutation attributed to the third class caused formation of cointegrates between the donor genome of phage carrying Tn-elements Tn3 or Tn5 and the recipient genome (bacterial chromosome).     

Detection of chemicals that stimulate Tn9 transposition in Escherichia coli K12

Summary A spot test has been developed for detecting substances that enhance the transposition of Tn9 in Escherichia coli. Phage :: Tn9-infected cells were plated on chloramphenicol media and a drop of the test substance was placed at the center of the plate. Following incubation, chloramphenicol-resistant colonies appeared due to the transposition of Tn9 to the bacterial chromosome. By comparing the test plate and a control plate with respect to the number and distribution of colonies, the effect of the test compound can be evaluated.Out of over 100 compounds tested, acetate, two detergents (Brij 58 and Nonidet P40) and dimethylsulfoxide were found to enhance transposition 3–20 fold. Acetate was also found to enhance the transposition of Tn5 and Tn10. The stimulating effect of Brij 58 was lost when palmitic acid was added with the Brij 58. The nature of these substances, which we refer to as transposagens, suggests an involvement of lipid or membrane in the transposition process.Abbreviations AMP-R, CAM-R, KAN-R, SPC-R, TET-R resistance to ampicillin, chloramphenicol, kanamycin, spectinomycin and tetracycline, respectively - DMSO dimethylsulfoxide A preliminary report of this work was presented at the Fifth Mid-Atlantic Extrachromosomal Genetic Elements Meeting, 1981 (Datta, Randolph and Rosner, Plasmid 7:99, 1982)     

High frequency mobilization of gram-negative bacterial replicons by the in vitro constructed Tn5-Mob transposon

Summary A DNA fragment of the broad host range plasmid RP4 carrying the cis-acting DNA recognition site for conjugative DNA transfer between bacterial cells (Mobsite) was cloned into the kanamycin-neomycin resistance transposon Tn5. Using conventrional transposon mutagenesis techniques the new transposon, called Tn5-Mob, can easily be inserted into the host DNA of gram-negative bacteria. A host replicon carrying Tn5-Mob is then mobilizable into any other gram-negative species if the transfer functions of plasmid RP4 are provided in trans. The potential of Tn5-Mob was demonstrated by mobilizing Rhizobium meliloti plasmids as well as the E. coli chromosome at high frequencies.     

Genetic analysis of Tn7 transposition

Summary The purpose of this work was to localize the DNA regions necessary for the transposition of Tn7. Several deletions of Tn7 were constructed by the excision of DNA fragments between restriction sites. The ability of these deleted Tn7s to transpose onto the recipient plasmid RP4 was examined. All the deleted Tn7s isolated in this work had lost their transposing capability. The possibility of complementing them was studied using plasmids containing all or part of Tn7. Two deleted Tn7s could not be complemented by an entire Tn7 indicating that a DNA sequence greater than the 42 bp terminal sequence is needed for recognition of the transposon by a transposition function. Four other deleted Tn7s could be complemented by Tn7. One of these was studied intensively in complementation experiments using different parts of Tn7 to obtain transposition. The results obtained allow us to propose that all genes needed for transposition of Tn7 onto plasmids are contained in a DNA segment of between 6.0 and 7.4 kb. Furthermore, one essential function must be contained in a DNA fragment longer than 2.5 kb on the right-hand end of Tn7. The classification of Tn7 with regard to the other transposable elements is discussed.